ISO/TTA 5:2007

TECHNOLOGY ISO/TTA 5
TRENDS
ASSESSMENT
Second edition
2007-10-15


Code of practice for creep/fatigue testing
of cracked components
Code de bonne pratique pour les essais de fluage/fatigue des
composants fissurés



Reference number
ISO/TTA 5:2007(E)
©
ISO 2007

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ISO/TTA 5:2007(E)
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ISO/TTA 5:2007(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards bodies
(ISO member bodies). The work of preparing International Standards is normally carried out through ISO
technical committees. Each member body interested in a subject for which a technical committee has been
established has the right to be represented on that committee. International organizations, governmental and
non-governmental, in liaison with ISO, also take part in the work. ISO collaborates closely with the
International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2.
The main task of technical committees is to prepare International Standards. Draft International Standards
adopted by the technical committees are circulated to the member bodies for voting. Publication as an
International Standard requires approval by at least 75 % of the member bodies casting a vote.
To respond to the need for global collaboration on standardization questions at early stages of technological
innovation, the ISO CounciI, following recommendations of the ISO/IEC Presidents' Advisory Board on
Technological Trends, decided to establish a new series of ISO publications named 'Technology Trends
Assessments' (ISO/TTA). These publications are the results of either direct cooperation with
prestandardization organizations or ad hoc Workshops of experts concemed with standardization needs and
trends in emerging fields.
Technology Trends Assessments are thus the result of prestandardization work or research. As a condition of
publication by ISO, ISO/TTAs shall not conflict with existing International Standards or draft International
Standards (DIS), but shall contain information that would normally form the basis of standardization. ISO has
decided to publish such documents to promote the harmonization of the objectives of ongoing
prestandardization work with those of new initiatives in the Research and Development environment. It is
intended that these publications will contribute towards rationalization of technological choice prior to market
entry. Whilst ISO/TTAs are not Standards, it is intended that they will be able to be used as a basis for
standards development in the future by the various existing standards agencies.
Attention is drawn to the possibility that some of the elements of this document may be the subject of patent
rights. ISO shall not be held responsible for identifying any or all such patent rights.
ISO/TTA 5 was prepared by VAMAS TWA25 and published under a memorandum of understanding
concluded between ISO and VAMAS.
This second edition cancels and replaces the first edition (ISO/TTA 5:2006), which has been technically
revised.

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ISO/TTA 5:2007(E)
Contents Page
1 EXECUTIVE SUMMARY . 1
2 SCOPE. 1
3 SPECIFIC OBJECTIVES. 2
4 INTRODUCTION. 2
4.1 Background to VAMAS Creep Crack Growth Initiatives . 3
4.2 Background to Industrial needs for validated Test Data . 3
4.3 Relevance of Testing Methods to Life Assessment Codes. 4
4.3.1 Background to Life Assessment Codes .4
4.3.2 Relation between laboratory tests and Component Assessment Codes . 5
4.3.3 Factors involved in the development of assessment codes. 5
4.4 Requirements for the VAMAS TWA 25 CoP . 6
4.5 ISO requirements . 6
4.5.1 ISO Technology Trend Assessment (ISO/TTA). 7
5 Acknowledgements . 7
5.1 List of participants in VAMAS TWS25. 7
6 NOMENCLATURE AND ABBREVIATIONS. 8
6.1 Nomenclatures . 8
6.2 Listing of abbreviations. 9
7 DESCRIPTION OF CREEP AND FATIGUE CRACKING. 10
7.1 Failure due Creep Crack Growth (CCG).10
7.2 Creep Crack Initiation (CCI) . 10
7.3 Transient crack growth conditions . 10
7.4 Steady state Creep Cracking (CCG). 10
7.5 Fatigue and Creep/Fatigue Crack Growth (FCG and CFCG) . 11
7.5.1 Failure due to fatigue. 11
7.5.2 Creep/Fatigue interaction. 11
7.6 Factors affecting CCI, CCG and CFCG .11
7.6.1 Creep properties . 11
7.6.2 Metallurgical effects. 12
7.6.3 Presence of residual stress fields. 12
7.6.4 Aggressive environments . 12
7.6.5 Anisotropic and inhomogeneous material characteristics . 12
8 TEST METHODS . 13
8.1 Overview . 13
8.2 Test Geometries . 13
8.3 Experimental Test Methods . 14
8.3.1 Material procurement. 14
8.3.2 Specimen selection. 14
8.3.3 Crack-plane orientation . 14
8.3.4 Specimen machining . 14
8.3.5 Specific size requirements. 15
8.3.6 Specific side-grooving requirements. 15
8.3.7 Shape of the crack front . 15
8.3.8 Pre-cracking to introduce a sharp flat crack front . 15
8.3.9 Pre-cracking for CCI tests. 15
8.3.10 Crack length measurements. 16
8.3.11 The use of Potential Drop (PD) . 16
8.3.12 Preparing the specimens for PD leads . 16
8.3.13 Specimen setup. 16
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ISO/TTA 5:2007(E)
8.3.14 Loading and creep displacement measurements .16
8.3.15 Displacement gauge.17
8.3.16 Heating of the specimens .17
8.3.17 Initial pre-load .17
8.3.18 Monitoring the temperature .17
8.3.19 Unplanned temperature excursions .17
8.3.20 Initial pre-load .18
8.3.21 Specimen loading .18
8.4 Data Collection.18
8.4.1 Detailed test and data monitoring.18
8.4.2 Data logging .18
8.4.3 Displacement measurements.18
8.5 Post-Test Measurements .19
8.5.1 Measurement of the final crack front.19
8.5.2 Crack tip bowing.19
8.5.3 Crack extension criteria .19
8.5.4 Crack deviation criteria .19
8.6 Recommended Minimum Number and Duration for Tests.20
8.6.1 Batch to batch variability .20
8.6.2 Minimum test requirements.20
8.6.3 Single point data per test.21
8.6.4 Multiple points data per test .21
8.6.5 Test duration requirements .21
8.7 Sensitivity and Accuracy Limits of the Results.21
8.7.1 Effects of data variability on correlation for FCG, CCG and CCI.21
8.8 Preparation of Test Data .22
8.8.1 Data collection .22
8.8.2 Time at which the test should be stopped .22
8.8.3 Smoothing the PD output data.22
8.8.4 Deriving the crack length from the PD output .22
8.8.5 Recommended number of data points .23
8.8.6 Calculating cracking and displacement rates .23
9 DATA ANALYSIS PROCEDURES .23
9.1 Choosing an appropriate CCI or CCG rate Correlating Parameter.23
9.1.1 Choice of parameter for correlating CCG .23
9.1.2 Choice of the C* term for CCG rate.23
9.1.3 Choice of parameter for CCI .24
9.2 Definitions for the relevant Fracture Mechanics Parameters .24
9.2.1 Stress intensity factor, K .24
9.2.2 J-integral.24
9.2.3 The C* parameter .24
9.2.4 Creep zone.25
9.2.5 Steady state creep .25
9.2.6 The C parameter.26
t
9.2.7 Small-scale creep.26
9.2.8 Interpretation of C* parameter.26
9.2.9 Time Dependant Failure Assessment Diagram (TDFAD) for CCI .26
9.2.10 The Q* Parameter.27
9.3 Criteria for Validity Checks of C* and K .27
9.3.1 Check for validity of C* .27
9.3.2 Components of displacement rates.27
9.3.3 Validity criteria for C* for highly ductile materials .28
9.3.4 Validity criteria for creep brittle materials.29
9.3.5 Transition time criteria for C* .29
10 REPORTING PROCEDURES .30
10.1 Details of test information to be reported .30
10.1.1 Report of findings.30
10.1.2 Pedigree of the material .30
10.1.3 Material properties to be logged .30
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ISO/TTA 5:2007(E)
10.1.4 Test machine description. 30
10.1.5 Details of starter crack . 30
10.1.6 Details for loading. 30
10.1.7 Report of data analysis. 30
10.1.8 Plots of data. 31
10.1.9 Tabulation of results. 31
10.1.10 Photographic/micrographic evidence. 31
10.1.11 Treatment of anomalous data. 31
11 CORRELATING CRACK GROWTH USING FRACTURE MECHANICS. 31
11.1 CCG rate analysis . 31
11.2 Crack Initiation (CCI) Analysis. 32
11.3 FCG rate Analysis . 32
11.4 Creep/fatigue crack growth rate analysis. 33
12 Methods for Calculating the C* Parameter . 33
12.1 Experimental Estimates of C* . 33
12.2 Reference Stress Method of Estimating C* . 34
13 APPENDIX I. 36
13.1 Test Specimen Geometries. 36
13.2 Geometry Definitions for Laboratory Specimens. 36
14 SPECIMEN FRACTURE MECHANICS PARAMETER SOLUTIONS. 38
14.1 Stress Intensity Factor K. 38
14.2 Solutions for the Y function. 38
14.2.1 Y factor for C(T). 39
14.2.2 Y factor for  CS(T) . 39
14.2.3 Y factor for for SEN(T) . 39
14.2.4 Y factor for SEN(B) (3 Point Bend Specimen). 39
14.2.5 Y factor for DEN(T). 40
14.2.6 Y factor for M(T) . 40
14.3 C* Solutions. 40
14.4 Reference Stress (σ ) Solutions. 41
ref
14.4.1 σ for C(T). 41
ref
14.4.2 σ for CS(T) . 42
ref
14.4.3 σ for SEN(T) . 42
ref
14.4.4 σ for SEN(B) (3 Point Bend Specimen). 42
ref
14.4.5 σ for DEN(T). 42
ref
14.4.6 σ for M(T) . 43
ref
14.5 η Functions for cracked geometries . 43
14.5.1 Nomenclature (see Figure A.1.3) . 43
14.5.2 Solutions for creep crack growth parameter, C* . 44
14.5.3 Best fit solutions of η from finite element calculations . 45

14.5.4 Choice of η for evaluating C* for material CCI and CCG properties. 45
14.5.5 Choice of η for evaluating C* in life assessment. 45
14.6 η Function Equations . 46
14.6.1 η functions for C(T). 46
14.6.2 η functions for CS(T) . 46
14.6.3 η functions for SEN(T). 46
14.6.4 η functions for SEN(B) — 3PB. 47
14.6.5 η functions for DEN(T). 47
14.6.6 η functions for M(T) . 47
LLD
14.7 Table for η . 49
CMOD
14.8 Table for η . 50
14.9 Geometry Definitions for 'Feature' Type Specimens. 51
14.9.1 Details form Pipe, Plate and Notched bar 'feature specimens' . 51
14.10 Fracture Mechanics Functions for Feature Components . 52
14.10.1 K solutions for pipes and plates. 52
14.10.2 Reference stress solutions for pipes. 53
14.10.3 Reference stress solutions for plates. 53
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ISO/TTA 5:2007(E)
14.10.4 Stress intensity factor K for the round notch bar .54
14.10.5 C* parameter for the notched bar.54
c
15 APPENDIX II :(TDFAD) K approach for CCI.55
mat
15.1 Introduction.55
15.2 Nomenclature.
...